Method for the treatment of exhaust gases containing organosilicon components or accompanying substances, and apparatus therefor

ABSTRACT

The invention relates to a method and an apparatus for treating exhaust gases comprising organosilicon components or accompanying substances. The invention more specifically relates to the use of bulk regenerator materials as storage materials allowing periodic removal, purification, and redelivery to the system. The invention solves the problem of clogged regenerator-storage materials during regenerative post-combustion of exhaust gases containing organosilicon components.

The present invention relates to a method and an apparatus for the treatment of exhaust gases containing organosilicon components and accompanying substances. More precisely, the present invention relates to a method for the regenerative postcombustion of exhaust gases containing organosilicon components, in which bulk storage materials (also referred to below as bulk regenerator materials) are periodically removed from the system, purified and recycled. Furthermore, the present invention relates to a system which permits automatic removal, purification and introduction (refilling) of the bulk storage materials in the regenerator.

PRIOR ART

Methods and apparatuses for the thermal purification of oxygen-containing or non-oxygen-containing exhaust gases are known, exhaust gases being fed to a combustion chamber heated, for example, by means of natural gas and being oxidized. If non-oxygen-containing exhaust gases are used, the supply of an additional oxidizing agent (e.g. air) is required. Such apparatuses and methods are generally referred to as thermal exhaust gas purification or thermal postcombustion. They serve, for example, for purifying the exhaust air from finishing, coating or printing operations which is laden with solvent vapors, i.e. for converting the solvents and other generally organic substances by oxidation into the nontoxic compounds carbon dioxide and steam if, for technical or economic reasons, recovery is not possible.

For economical operation of such an apparatus, use of waste heat is provided in by far the most cases. This may both serve for the generation of process heat and have the aim of reducing the fuel demand of the exhaust gas purification apparatus by preheating the exhaust gas to be treated. Extremely high exhaust gas preheating temperatures and hence low fuel consumption can be realized by so-called regenerative exhaust gas preheating based on cyclically switchable ceramic storage beds. For distinguishing from the conventional mode of operation using a tube-bundle-based exhaust gas preheater (recuperator) which is generally known by the term TPC plant (Thermal Post-Combustion), an RPC plant (Regenerative Post-Combustion) or RTO plant (Regenerative Thermal Oxidation) is referred to here.

In numerous processes (e.g. regranulation of plastics, plastics compounding processes, coating processes, drum reconditioning, treatment of plastics wastes for utilization, landfills, MBA plants), however, exhaust gases which contain, inter alia, organosilicon components form. In this case, use of the RPC technology has been prevented up until now by the fact that the regenerator storage materials are amorphously coated with the oxidation product (predominantly SiO₂) from the organosilicon compounds and thus become clogged. The periodically necessary maintenance requires the manual dismantling of the usually monolithic storage materials (honeycombs), individual cleaning (steam jet) and manual reinstallation. This effort is not acceptable both with regard to the working conditions and with regard to the labor involved. In this context all manufacturers of RPC plants have to date ruled out the treatment of organosilicon compounds in their technical offer documents.

However, the adhesions of silica occur not only in RPC plants but also in conventional thermal postcombustion plants with recuperative exhaust air preheating. However, complete clogging does not always occur here, but here too cases are known in which plant shutdowns and damage due to excessive temperature have occurred within a short time due to silica adhesions.

The term “organosilicon compounds” is defined in the literature inter alia as follows: “in the narrower sense, a designation for those compounds which contain direct silicon-carbon bonds. There are . . . also compounds in which the carbon is linked to the silicon via oxygen, nitrogen or sulfur atoms”.

Organosilicon compounds occur in particular in the following areas:

-   -   silicon surfactants as foam stabilizers in plastics     -   silicones as lubricants for plastics processing, in hand         protection ointments, fragrances, toothpaste, etc.     -   as silicone elastomers, silicone enamel, silicone fats, silicone         gum, silicone resins, silicone oils, silicone rubber, silicone         impregnating agents, etc.     -   organofunctional silanes as adhesion promoters     -   organooxysilanes and siloxanes as synthetic lubricants,         crosslinking agents in cold rubbers, etc.

Organosilicon compounds are furthermore used as food additives, special cleaning agents, paper and textile coatings, color additives, etc.

The prior art therefore discloses no plants and processes which permit treatment of exhaust gases containing organosilicon compounds with the aid of regenerative exhaust gas preheating.

Starting from this, it is the object of the invention to provide a method and an apparatus which permits the use of the RPC technology and of the TPC technology also in the case of organosilicon exhaust gas components and greatly simplifies the handling of the adhesions.

BRIEF DESCRIPTION OF THE INVENTION

The underlying object was achieved by initially allowing adhesion to the bulk regenerator materials and removing the coated bulk regenerator materials periodically, according to requirements, purifying them and reintroducing them. This step can optionally be carried out in an automated manner.

The aim of the present invention is therefore to provide a method for exhaust gas purification with regenerative exhaust air preheating, the exhaust gases containing organosilicon components. This method comprises that the heat storage material comprising a bed initially retains, as a filter, the silica formed by oxidation of the organosilicon compounds and the bed is periodically removed from the regenerator or from the regenerators, worked up and recycled to the system.

The invention furthermore relates to an apparatus for the thermal purification of an oxygen-containing or non-oxygen-containing exhaust gas which contains inter alia organosilicon compounds, characterized in that the apparatus comprises a bulk material discharge, a separation apparatus and a bulk material feed.

DESCRIPTION OF FIGURES

FIG. 1 a schematic diagram which shows an apparatus according to the invention for the oxidative purification of exhaust gases containing organosilicon compounds and regenerative exhaust gas preheating, which is in the form of a one-tower system;

FIG. 2 shows the apparatus according to FIG. 1 in the operating phase of heating up;

FIG. 3 shows the apparatus according to FIG. 1 in the operating phase of downward flow;

FIG. 4 shows the apparatus according to FIG. 1 in the operating phase of upward flow;

FIG. 5 shows, in simplified form, the temperature curve in the regenerator of an apparatus according to FIG. 1 in the operating phases of upward and downward flow;

FIG. 6 shows the function of bed purification of the apparatus according to FIG. 1;

FIG. 7 shows an embodiment of the apparatus according to FIG. 1 as a two-tower system.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a method for the treatment of exhaust gases containing organosilicon components or accompanying substances. This method is characterized in that the storage materials of the regenerator are easily removed from the system, are purified in a separation apparatus and are recycled to the regenerator.

The storage material is at least partly a bed, a bulk material, such as, for example, spheres, e.g. solid or hollow spheres. The bulk material can preferably consist of ceramic or steel. Other materials which can be used as bulk material include: pebbles, expanded clay, larva and similar materials which have the same effect as that mentioned above. In one embodiment, the storage material may consist only of bulk material. In another embodiment, the storage material contains at least 20%, e.g. 30%, 40% or 50%, such as 60%, 70%, 80% or 90% of bulk material.

The removal, purification and recycling step can be effected automatically or semiautomatically. The method is preferably characterized in that the regenerative preheating and cooling as well as the oxidation of the exhaust gas are effected within a regenerator bed which is operated alternately with upward and downward flow. If necessary, a flushing cycle with the aid of intermediate storage of the exhaust gas can be carried out.

According to the invention, two or more regenerator beds which are connected to a separation space and through which flow takes place alternately are used in the method, each of these regenerator beds being equipped with an apparatus for removal and introduction (refilling) of the heat storage material. The purification or separation can be effected in a common separation apparatus or in separate separation apparatuses.

The removal, purification and the introduction of the heat storage material can be effected at successive times in the individual regenerators.

In a preferred embodiment, the time of working up the storage material is determined by measuring the flow resistance of the exhaust air flowing through. When a maximum permissible pressure drop of the plant is exceeded, reprocessing of the storage materials then takes place. Alternatively, the heat storage material can be purified after certain time intervals, for example during a downtime at the weekend.

In a further embodiment, the regenerator may consist not completely but only partly of a removable bed. This region of the bed is present in the sections which are referred to as reaction zones or as combustion space.

In regions of the exhaust air regenerator or clean gas regenerator, the storage material may also consist of conventional components, such as honeycombs.

Furthermore, the method according to the invention does not require complete regenerative exhaust gas preheating; rather the exhaust gas preheating can also be brought about by another route, such as a recuperative route.

The optionally additionally required energy can be introduced by admixing natural gas into the exhaust gas, electrically, via a burner or by injecting gas into the combustion space.

The apparatus according to the invention therefore comprises, in addition to the known design of an RPC or TPC plant or RTO plant, a discharge which is mounted on each regenerator; the bed can be removed from the regenerator through this discharge and can be fed to a separation apparatus. This separation apparatus separates SiO₂ deposits from the bulk material. For example, at least some of the adhesions are detached by friction. Alternatively the deposits can be detached by pressure spraying or ablative methods. The separation apparatus is a conventional separation apparatus, such as a sieve, which is well known to the person skilled in the art in this area.

The purified bulk storage material is then recycled to the regenerator through a feed, optionally via a transport device.

The apparatus may comprise one regenerator or a plurality of regenerators. Each of these regenerators has a discharge and a feed for the bulk material.

The main components of an embodiment of the apparatus according to the invention are shown in FIG. 1. The key plant component then is the regenerator tower which is filled with a bed comprising heat storage material. Arranged at the top and bottom in each case are inlets and outlets (2, 3) for the exhaust gas and clean gas, respectively, which permit alternate flow through the regenerator tower from bottom to top (upward flow) or from top to bottom (downward flow) via a butterfly valve system (4 to 7) by means of cyclic switching. For heating up the plant, a burner (8) which is supplied with natural gas and air via corresponding control valves (interconnection, 9) is installed at the top of the regenerator. During the exhaust gas purification mode of the plant the energy required in the case of low loadings of the exhaust is supplied with the aid of a feed of the gaseous additional fuel directly into the exhaust gas (10), and the burner (8) is switched off. For purification of the bed material this can be removed via a discharge (15) below the regenerator and, after passing through a separation apparatus (16), is refilled (18) by means of a transport device (17) above the bed.

The different operating phases of the apparatus are shown schematically in FIGS. 2 to 6. There the respective active material flows are characterized with directional arrows.

In the heat-up mode corresponding to FIG. 2 the regenerator bed (1) is first heated with the aid of the burner (8). The supply of the combustion air delivered by means of a fan (12) is regulated in association with the natural gas (control valves 9) as a function of the combustion space temperature. The heat-up process ends when the upper part of the regenerator bed (1) is heated to a sufficient temperature. Thereafter, the temperature maximum is driven into the middle of the regenerator by a special switching program of the valves (4 to 7). For this purpose fresh air is passed through the plant via the main fan (11) with butterfly valve (13) opened and butterfly valve (14) closed, which fresh air is treated with natural gas in a controlled manner via valve (10) for maintaining the temperature. The burner (8) is switched off during this procedure.

After the heat-up phase is complete, the plant goes over into normal operation. For this purpose, the fresh air supply (13) is closed and the exhaust gas laden with organosilicon constituents (butterfly valve 14) is switched on. During normal operation, a distinction can be made between the operating states of downward flow (FIG. 3) and upward flow (FIG. 4). The corresponding temperature curves over the reaction route are shown in simplified form in FIG. 5.

During downward flow, the exhaust gas is, according to FIG. 3, fed (2) to the regenerator from the top via the opened butterfly valve 4 (butterfly valve 5 closed) and flows downward through said regenerator. The exhaust gas is heated approximately to the middle of the regenerator and the organic substances present therein oxidize (temperature jump). The oxidation product SiO₂ of the organosilicon compounds forms amorphous adhesions on the heat storage material and is thus retained. In the further course of the flow, the clean gas releases its heat again to the storage material before it leaves the regenerator again at the bottom (3) and is passed via the opened butterfly valve 7 (butterfly valve 6 closed) to the chimney.

After a defined time, switching to the operating state of upward flow (FIG. 4) is effected. The exhaust gas now flows via the opened butterfly valves 5 and 6 (butterfly valves 4 and 7 closed) from bottom (3) to top (2) through the regenerator. The temperature curve shown by dashed lines in FIG. 5 results, once again the silica adhesions intentionally occurring approximately in the middle part of the regenerator. The two operating states of downward and upward flow are passed through cyclically in sequence.

For maintaining the reaction temperature, natural gas is again added to the exhaust gas (control valve 10) and the burner remains switched off. For avoiding switching peaks of the clean gas emissions of organically bound carbon (C_(org.)), temporary storage of the exhaust gas, not shown here for the sake of clarity, can be employed.

In the course of time, the silica adhesions increasingly build up within the ceramic storage material so that there is increased flow resistance. This can be detected by a differential pressure measurement, cleaning of the bed being effected in a preferred embodiment after a maximum pressure drop value is exceeded. For this purpose, the bed is cooled in a controlled manner in a pause in operation (e.g. at the weekend) and is put into the operating state of bed cleaning according to FIG. 6. The bed material including the resulting adhesions is removed via the discharge (15) and fed to a separation apparatus (16), some of the adhesions flaking off directly as a result of the relative movements between, for example, the packings (e.g. solid or hollow spheres of ceramic or steel). The remaining SiO₂ adhesions are separated from the storage material in the separation apparatus, while the purified storage material passes via a transport device (17) back into the regenerator (18). After bed cleaning is complete, the plant is heated up again and goes over into the exhaust gas purification mode.

Essential to the invention is the procedure initially to permit the silica adhesions formed from the oxidation of the organosilicon compounds within the regenerator and to remove the storage material, such as the bed, discontinuously depending on requirements (e.g. exceeding of pressure difference) and to recycle it in purified form to the plant.

In the concept of the invention, numerous modifications and further developments are possible, which relate, for example, to the discharge apparatus, the embodiment of the storage material or the arrangement of the regenerators.

FIG. 7 schematically shows, for example, a variant of the apparatus according to the invention, comprising two separate regenerator chambers. Here, the preheating of the exhaust gas is effected in one regenerator, while the second regenerator is heated with the clean gas stream. The oxidation of the pollutants in the exhaust gas begins within the first regenerator and final combustion can take place under conditions which can be set in a defined manner (residence time, temperature) in the combustion space arranged above the regenerators. The purification of the bed material is carried out analogously to the procedure according to FIG. 6 in the two regenerators simultaneously or optionally in succession (displaceable transport and separation device, as shown in FIG. 7). The installation of a third regenerator for realizing flushing prior to treatment with clean gas is also possible in the concept of the invention.

In addition, the invention can also be applied to adhesions within RPC plants which were formed in a manner other than by oxidation of organosilicon compounds. Furthermore, the present invention can also be used in TPC plants in which exhaust gases, the organosilicon components or accompanying substances are treated. 

1. A method for operating an exhaust gas purification system for exhaust gas which contains organosilicon compounds, comprising the steps of: treating said exhaust gas in a regenerator with a heat storage material at least a portion of which is in the form of bulk material and which forms a bed, said treating step results in the formation of adhesions containing silica, formed by oxidation of organosilicon compounds, on said heat storage; removing at least a portion of said heat storage material of said bed from said regenerator after adhesions are formed on said heat storage material from oxidation of said organosilicon compounds; purifying the heat storage material removed from said regenerator by removing adhesions from said heat storage material; and re-introducing the heat storage material purified in said purifying step into the regenerator to refill the bed.
 2. The method as claimed in claim 1, wherein the steps of removing, purifying and re-introducing of the heat storage material is effected automatically or semiautomatically.
 3. The method as claimed in claim 1, wherein the treating step is performed in the regenerator alternately with upward and downward flow.
 4. The method as claimed in claim 3, further comprising the step of flushing the regenerator.
 5. The method as claimed in claim 1, wherein the regenerator includes two or more regenerators each with beds which are connected to a combustion space, and through which flow takes place alternately between the two or more regenerators, and wherein each of said two or more regenerators are equipped with an apparatus for removal and re-introduction of the heat storage material after purification using a separation apparatus.
 6. The method as claimed in claim 2, wherein said regenerator includes two or more regenerators, and wherein performing said steps of removing, purifying, and re-introducing the heat storage material is effected at successive times in individual regenerators of said two or more regenerators.
 7. The method as claimed in claim 1, further comprising the step of detecting a pressure drop across said bed of said heat storage material and performing said steps of removing, purifying, and re-introducing said heat storage material after a maximum permissible pressure drop is exceeded.
 8. The method as claimed in claim 1, wherein the steps of removing, purifying, and re-introducing said heat storage material are performed after after certain time intervals.
 9. The method as claimed in claim 1, wherein said step of removing removes only partly said heat storage material.
 10. The method as claimed in claim 1, wherein said treating step includes preheating not completely in a regenerative manner.
 11. The method as claimed in claim 1, wherein the heat storage material which forms the bed consists of solid or hollow spheres.
 12. The method as claimed in claim 1, wherein the regenerator includes two or more regenerators, each of which have a discharge connected to a separation apparatus. 